Flotation reagent and process

- Minerec Corporation

The performance of xanthogen formates as reagents for the flotation of sulfide copper ores is significantly improved by reacting the xanthogen formate with an aromatic amine. In a preferred embodiment, up to about 20% of an aromatic diamine, most particularly o-phenylene diamine and o-toluene diamine, is used.

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Description
BACKGROUND OF THE INVENTION

The present invention relates generally to flotation reagents and, more particularly, to xanthogen formate flotation reagents useful in the concentration of copper sulfide ores. The invention is carried out by reacting aromatic amines with an excess of alkyl xanthogen formate, in various proportions, to yield a stable composition of unreacted xanthogen formate and a complex mixture of the reaction products.

Alkyl xanthogen formates are defined by the general formula ##STR1##

where R and R' are lower alkyl radicals, generally with 1 to 6 carbon atoms. These compounds have been successfully used as reagents for the flotation of sulfide copper ores for over thirty years (see U.S. Pat. No. 2,412,500, issued Dec. 10, 1946). They are generally referred to as flotation promoters, and are used in conjunction with other well known flotation reagents, e.g. pine oil, methyl isobutyl carbinol (MIBC), lime, cyanide, etc.

Copper sulfide ores are complex, both physically and chemically, and they are quite variable, even on a day-to-day basis from the same source. The flotation process itself has a large number of variables, and some of these are difficult to control and even to measure. Because of this complexity, the process of finding new and improved flotation promoters, while grounded in chemical theory, relies on side-by-side comparisons of such compounds and known promoters, with all other conditions being held the same.

OBJECTS OF THE INVENTION

A general object of the present invention is to provide an improved flotation reagent of the xanthogen formate type.

Another object of the present invention is to provide an improved flotation reagent for copper sulfide ores.

A more particular object of the present invention is to provide a flotation reagent specifically adapted for the leach/precipitation/flotation method of treating oxidized copper sulfide ores.

Various other objects and advantages of the invention will become clear from the following description of embodiments thereof, and the novel features will be particularly pointed out in connection with the appended claims.

DESCRIPTION OF EMBODIMENTS

The present invention is based on the discovery that aromatic amines not only react with xanthogen formates, but that a mixture of said formate with the product of the reaction (e.g. a reaction mixture including excess of the xanthogen formate) is an improved flotation promoter and frother. The mixture is stable, and is considerably more active as a flotation promoter than the xanthogen formate alone.

The aromatic diamines which are preferred are the simplest available: phenylene diamine (diamino benzene) and toluene diamine. Monoamines which may be used include toluidine and xylidine. The ortho isomers are generally preferred.

The dialkyl xanthogen formates used are those with proven utility as flotation promoters: amyl xanthogen ethyl formate, ethyl xanthogen ethyl formate, butyl xanthogen ethyl formate, isopropyl xanthogen ethyl formate, etc.

The reaction is somewhat exothermic with gas evolution, but the manner in which it is carried out is not deemed critical. The preferred procedure with diamines is to cool the xanthogen formate to about 15.degree. C. The diamine is melted, as most are solid at room temperature (o-phenylene diamine melts at 102.degree. C.; o-tuluene diamine melts at 64.degree. C.). Under conditions of agitation, the amine is added slowly to the xanthogen formate. Gas evolution is observed to cease after about 15 minutes and the temperature of the mixture rises to about 40.degree. C. Stirring is continued for another hour, and the product is cooled and packed. The only critical aspect of the reaction is that all of the amine react and that there be an excess of unreacted xanthogen at completion. With the monoamines, the reactants (liquids) can be mixed at room temperature, and the mixture will rise to about 60.degree. C.

Monoamines can be used in up to about molecular proportions, roughly 40% (all percentages are weight percent) of the reactants. Diamines, by contrast, should not be added in excess of about 20% of the reactant weight, as higher additions produce a sticky and unmanageable product. Thus, the preferred addition levels for the aromatic monoamines is 5-40% and for the diamines it is 5-20%.

It is known that when the reactants are 80% xanthogen and 20% diamine, about 80% of the former reacts, so the 20% diamine addition is considered a safe upper limit.

The invention is particularly advantageous in the treatment of partially oxidized copper ores treated by the leach/precipitation/float, or LPF process. The ore is initially leached with an acid to dissolve soluble constituents, and then cemented on iron to precipitate dissolved copper. The resulting pulp is then subjected to froth flotation to recover a sulfide concentrate.

In Examples 1-12, aqueous pulps with a pH of approximately 2.0 containing sulfide ore and cement copper resulting from leach-precipitation treatment of partially oxidized sulfide ore of the compositions indicated with respect to copper, were subjected to froth flotation operations in the presence of the reagents indicated, but otherwise under substantially identical conditions with the production of concentrate and tailing products of the analyses shown. In the examples .28 lbs of the reagents were employed, together with 0.12 lbs of pine oil per ton of ore. The brackets are intended to indicate a reacted mixture including excess formate.

Examples 1-6 ______________________________________ Ore Assaying .91% Cu Concentrate Tailing Reagents % Cu % Cu ______________________________________ 1. Ethyl xanthogen ethyl formate 6.61 0.186 2. (90% ethyl xanthogen ethyl for- mate +10% o-phenylene diamine) 7.12 0.135 3. (90% isopropyl xanthogen ethyl formate +10% o-phenylene diamine) 8.32 0.132 4. (90% n-butyl xanthogen ethyl for- mate +10% o-phenylene diamine) 7.62 0.110 5. (95% n-butyl xanthogen ethyl for- mate +5% o-phenylene diamine) 8.62 0.126 6. (90% isobutyl xanthogen ethyl for- mate +10% o-phenylene diamine) 7.62 0.116 ______________________________________

Examples 7-12 ______________________________________ Ore Assaying 1.196% Cu Con- Tail- centrate ing Reagents % Cu % Cu ______________________________________ 7. Butyl xanthogen ethyl formate 8.69 0.283 8. (90% butyl xanthogen ethyl formate +10% o-phenylene diamine) 7.77 0.204 9. (90% butyl xanthogene ethyl formate +10% o-toluene diamine) 8.38 0.170 10. Amyl xanthogen ethyl formate 8.07 0.289 11. (90% amyl xanthogen ethyl formate +10% o-phenylene diamine) 8.58 0.207 12. (90% amyl xanthogen ethyl formate +10% o-toluene diamine) 7.66 0.179 ______________________________________

In the following examples, sulfide ores of the composition indicated with respect to copper were ground in water to form aqueous pulps which were subjected to froth flotation operations in the presence of the reagents indicated but otherwise under identical conditions with the production of concentrate and tailing products of the analyses indicated.

Example 13 ______________________________________ Ore Assaying .601% Cu ______________________________________ Concentrate % Cu 14.22 14.05 15.02 Tails % Cu 0.151 0.138 0.141 % Recovery Cu 75.70 77.87 77.04 Reagents: Lbs. per ton Lime 4.0 4.0 4.0 Pine oil .06 .06 .06 Butyl ethyl thionocarbamate .04 -- -- (90% amyl xanthogen ethyl formate +10% o-phenylene diamine) -- .04 -- (90% ethyl xanthogen ethyl formate +10% o-toluene diamine) -- -- .04 ______________________________________

Example 14 ______________________________________ Ore Assaying .622% Cu ______________________________________ Concentrate % Cu 8.61 8.27 8.34 Tails % Cu .186 .148 .148 % Recovery Cu 71.70 77.65 77.65 Reagents: Lbs per ton Lime 6.0 6.0 6.0 Burner oil .04 .04 .04 MIBC .12 .12 .12 Isopropyl ethyl thionocarbamate .04 -- -- (90% amyl xanthogen ethyl formate +10% o-phenelene diamine) -- .04 -- (90% amyl xanthogen ethyl formate +10% o-toluene diamine -- -- .04 ______________________________________

Example 15 ______________________________________ Ore Assaying .679% Cu ______________________________________ Concentrate % Cu 15.84 15.14 15.86 Tails % Cu .088 .078 .081 % Recovery Cu 87.48 88.94 88.56 Reagents: Lbs. per ton Lime .8 .8 .8 Cyanide .015 .015 .015 MIBC .18 .18 .18 Sodium cresyl dithiophosphate 0.34 0.34 0.34 (80% butyl xanthogen ethyl formate +20% o-toluene diamine) -- .01 -- (80% methyl amyl xanthogen ethyl formate +20% o-toluene diamine) -- -- .01 ______________________________________

Example 16 ______________________________________ Ore Assaying .906% Cu ______________________________________ Concentrate 10.43 9.01 Tails % Cu .272 .219 % Recovery Cu 71.6 77.6 Reagents: Lbs per ton Lime 5.4 5.4 Burner oil .08 .08 Pine oil .08 .08 Isopropyl ethyl thionocarbamate .06 -- (90% amyl xanthogen ethyl formate +10% o-phenylene diamine) -- .06 ______________________________________

The actual reaction mechanism between the xanthogen formate and the aromatic diamine is not known with precision; a large number are possible, and it is known that both mono- and di-substituted products result. The invention is thus defined as the reaction product of xanthogen formate and an aromatic amine, generally in the presence of excess formate.

Examples 17-21 show the improved recoveries that are attained when the promoter is a xanthogen formate and the reaction product of the formate and a monoamine.

Example 17 ______________________________________ Ore Assaying .804% Cu ______________________________________ Concentrate % Cu 7.18 7.00 Tails % Cu .155 .140 % Recovery 82.46 84.33 Reagents: Lbs. per ton Lime 3.2 3.2 MIBC .08 .08 Sodium isopropyl xanthate .01 .01 Ethyl xanthogen ethyl formate .03 -- (80% ethyl xanthogen formate +20% o-toluidine) -- .03 ______________________________________

Example 18 ______________________________________ Ore Assaying .804% Cu ______________________________________ Concentrate % Cu 6.42 6.45 Tails % Cu .153 .142 % Recovery 82.96 84.20 Reagents: Lbs. per ton Lime 3.2 3.2 MIBC .08 .08 Sodium isopropyl xanthate .01 .01 Ethyl xanthogen ethyl formate .03 -- (72% ethyl xanthogen ethyl formate +28% o-toluidine) -- .03 ______________________________________

Example 19 ______________________________________ Ore Assaying .818% Cu ______________________________________ Concentrate % Cu 7.43 7.20 6.26 Tails % Cu .136 .132 .128 % Recovery Cu 84.96 85.45 86.06 Reagents: Lbs per ton Lime 2.8 2.8 2.8 MIBC .08 .08 .08 Sodium isopropyl xanthate .01 .01 .01 Ethyl xanthogen ethyl formate .03 -- -- (95% ethyl xanthogen ethyl formate +5% o-toluidine) -- .03 -- (92% ethyl xanthogen ethyl formate +8% o-toluidine) -- -- .03 ______________________________________

Example 20 ______________________________________ Ore Assaying .818% Cu ______________________________________ Concentrate % Cu 6.79 7.04 Tails % Cu .130 .124 % Recovery 85.70 86.31 Reagents: Lbs. per ton Lime 2.8 2.8 MIBC .08 .08 Sodium isopropyl xanthate .01 .01 Ethyl xanthogen ethyl formate .03 -- (66% ethyl xanthogen ethyl formate +34% o-toluidine) -- .03 ______________________________________

Example 21 ______________________________________ Ore Assaying .804% Cu ______________________________________ Concentrate % Cu 7.84 6.73 Tails % Cu .151 .138 % Recovery 82.83 84.45 Reagents: Lbs. per ton Lime 2.8 2.8 MIBC .08 .08 Sodium isopropyl xanthate .01 .01 Ethyl xanthogen ethyl formate .03 -- (63% ethyl xanthogen ethyl formate +37% xylidine) -- .03 ______________________________________

Various changes in the details, steps and materials, which have been herein described and illustrated in order to explain the invention, may be made by those skilled in the art within the principle and scope of the invention as defined in the appended claims.

Claims

1. A flotation promoter comprising a mixture of:

an alkyl xanthogen formate having alkyl radicals of 1-6 carbon atoms; and
the reaction products of said xanthogen formate and an aromatic amine selected from the group consisting of o-toluene diamine, o-phenylene diamine, o-toluidine and o-xylidene, said amine comprising 5-40 wt.% of the reaction mixture.

2. The flotation promoter as claimed in claim 1, wherein said amine is a diamine, and comprises about 5 to 20 wt.% of the reaction mixture.

3. A flotation promoter consisting essentially of a fully reacted mixture of an alkyl xanthogen formate with alkyl radicals of 1-6 carbon atoms and an aromatic diamine selected from the group consisting of o-toluene diamine and o-phenylene diamine, said diamine comprising 5 to 20 wt.% of the reaction mixture.

4. A flotation promoter consisting essentially of a fully reacted mixture of an alkyl xanthogen formate with alkyl radicals of 1-6 carbon atoms and an aromatic monoamine selected from the group consisting of o-toluidine and o-xylidine, said monoamine comprising 5 to 40 wt.% of the reaction mixture.

5. The process for beneficiating copper sulfide ores by froth flotation in the presence of a flotation promoter to recover copper concentrate comprising:

providing an aqueous pulp of said ore;
adding as said promoter a mixture of an alkyl xanthogen formate with alkyl radicals of 1-6 carbon atoms and the reaction product of said xanthogen formate and an aromatic amine selected from the group consisting of o-toluene diamine, o-phenylene diamine, o-toluidine and o-xylidine, said amine comprisine 5 to 40 wt.% of the reaction mixture; and
recovering a copper concentrate.

6. The process for producing an improved flotation reagent comprising:

providing an alkyl xanthogen formate having alkyl radicals of 1-6 carbon atoms;
cooling the formate and adding thereto under conditions of agitation the indicated percent of a liquid aromatic amine selected from the group consisting of o-toluene diamine (5-20%) o-phenylene diamine (5-20%) o-toluidine (5-40%) and o-xylidine (5-40%), said percentages being wt. percents of the reaction mixture; and
recovering the resulting mixture comprising unreacted xanthogen formate and the liquid reaction products of said xanthogen formate and said amine.
Referenced Cited
U.S. Patent Documents
1394640 October 1921 Perkins
1640218 August 1927 Sayre
1652099 December 1927 Douglass
1847664 March 1932 Ney
2024925 December 1935 Hirschkind
2070634 February 1937 Weintz
2278020 March 1942 Ralston
2412500 December 1946 Fischer
2629494 February 1953 Brown
2644580 July 1953 Robbins
2691635 October 1954 Harris
2711421 June 1955 Mull
3425550 February 1969 Baarson
3855263 December 1974 Melloni
Foreign Patent Documents
507566 June 1974 SUX
Patent History
Patent number: 4136020
Type: Grant
Filed: Nov 11, 1976
Date of Patent: Jan 23, 1979
Assignee: Minerec Corporation (New York, NY)
Inventor: Arthur H. Fischer (New York, NY)
Primary Examiner: Robert Halper
Attorney: James J. Burke, II
Application Number: 5/740,844
Classifications
Current U.S. Class: With Modifying Agents (209/166); Froth-flotation Or Differential Adherence (252/61); 260/455A
International Classification: B03D 102;